FI105366B - Linearization procedure and amplifier arrangement - Google Patents

Abstract

The invention relates to a linearization method and an amplifier arrangement, in which a signal to be amplified is predistorted by utlilizing digital predistortion information stored in the memory of a predistortion controller. Predistortion means predistort the signal to be amplified in its analogue form, the predistortion is adapted at least to the signal to be amplified, the predistorion information stored in the memory of the controller correspond to the variables of polar coordinates, such as phase and amplitude, and the phase and amplitude of the signal to be amplified are distorted in the predistortion in accordance with the predistortion information located in the memory of the controller.

Description

105366

Linearization Method and Amplifier Arrangement, Field of the Invention

The present invention relates to a linearization method in which the signal to be amplified is pre-distorted by utilizing stored digital-5 pre-distortion data.

The invention also relates to an amplifier arrangement comprising pre-distortion means and a memory in which digital pre-distortion information is stored.

Background of the Invention

The radio frequency power amplifiers have a range greater than 10 small signal amplifiers and thus the power amplifiers are non-linear. For example, the base station of a cellular radio system receives and amplifies signals of different frequencies of several terminals simultaneously. In prior art solutions, signal distortion caused by intermodulation of power amplifiers has been addressed by using feed-forward field or pre-distortion. In feed-in solutions, typically two control loops are used, which have a main amplifier for the actual signal and a distortion amplifier for the signal distortion. The distortion feedback is then used to correct the actual signal.

, Y. The prior art solution using a predistortion makes an estimate of how the amplifier will distort the signal.

• · · s- '.' The signal to be amplified by the estimate is pre-distorted by a distortion conversion opposite to that of the amplifier. In this case, when confirming

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at the same time, the amplifier compensates for the distortion and the amplifier comes out "undistorted". linearized signal, v; In prior art solutions, the pre-distortion is performed either analogously or digitally. Note: Changing the amplifier distortion: T: is difficult in analog pre-distortion and therefore digital: T: pre-distortion is more advantageous. Digital pre - distortion provides -. / Very powerful distortion correction. Typical digital pre-distortion is performed using look-up tables, which preferably need to be updated to provide adaptability, since amplifier distortion is affected by, among other things, temperature, amplifier age, and signal input to the amplifier. Such a solution is disclosed, for example, in U.S. Patent No. 5,049,832, which is incorporated herein by reference. In the solution 35 of the publication, the precursor data is stored in memory in the form of a rectangular coordinate system which has been used to reduce the amount of data to be stored and thus to accelerate the adaptability of the solution under changing circumstances.

However, the problem with this kind of fully digital pre-distortion is typically slowness. With current digital signal processing technology, bandwidth can be a few tens, up to hundreds of kilohertz, using complex gain pre-distortion. The bandwidth is even smaller when using polar pre-distortion due to abundant transform calculations. In addition, the problem of digital pre-distortion is the estimation of this delay of the power amplifier.

Brief Description of the Invention

It is therefore an object of the invention to provide a method and an arrangement implementing the method so that the above problems can be solved. The invention avoids the slowness of digital pre-distortion and the poor applicability of analog pre-distortion to changes.

This is achieved by a method of the type described in the preamble, characterized in that the signal to be amplified is pre-distorted in its analog form, the pre-distortion is adapted to the signal to be amplified, the pre-distortion information stored in memory corresponds to polar coordinates: V: 20 ton such as phase and amplitude; the phase and amplitude of the signal to be tuned according to the pre-distortion data.

• *. ···. The amplifier arrangement according to the invention, in turn, is characterized by the fact that the pre-distortion means are adapted to distort the signal to be amplified in its analog form, the receiver arrangement is adapted to adapt to the pre-distortion amplified signal, the distortion data stored in memory are other polar coordinates. phase and amplitude and biasing means are adapted to distort the phase and amplitude of the signal according to the bias information.

A number of advantages are achieved by the method and system of the invention. Calculations that take time for digital pre-distortion can be replaced by a table search. The invention has also enabled the use of polar representation in broadband applications.

*: Short description of the figures

The invention will now be further described in connection with preferred embodiments 35, with reference to the accompanying drawings, in which: 105366 3

Figure 1 shows a pre-distorting amplifier and

Figure 2 illustrates a bias controller.

DETAILED DESCRIPTION OF THE INVENTION

The invention is particularly applicable to, but not limited to, a cellular radio system in a base station transmitter power amplifier.

Figure 1 shows a pre-distortion amplifier arrangement according to the invention. The arrangement comprises a signal divider 102, a phase preamplifier 104, an amplitude preamplifier 106, a power amplifier 108, a distortion controller 10 110, a suppressor 112, an amplitude distortion 114, a phase distortion 116, a delay means 118, an adder 120, a first integrator 122, a first amplifier 124, a low-pass filter 126, a multiplier 128, a second integrator 130, a second amplifier 132, a second low-pass filter 136, a first high-pass filter 136 and a second high-pass filter 138. The multiplier 130, a quadrature demodulator, comprises a multiplier 160, a phase shift the signal divider 164. The arrangement may further comprise a feed-in amplifier 142 and an adder 144 in which an error signal 176 is subtracted from the output signal 170 to reduce interference. The arrangement works as follows. First let's look at the direct operation of the amplifier: V: 20. The signal to be amplified 100 is divided into two divisions 102. The upper signal further advances to the preconditioning means 104 and 106, where the phase and amplitude of the signal 100 is changed. The phase and amplitude converters 104 and 106 alter or distort the phase and amplitude of the signal 100 to the amplifier 108 such that the output • · · 25 of the amplifier 108 is substantially undistorted.

Consideration will now be given to the generation of the error signal 176. Initially, a modulation signal vm 174 is formed such that the signal 100 to be amplified propagates through divider 102 to the distortion generating means 114 and 116 forming the expected value of the signal, after which the signal is delayed in the delay means 118. In this case, the signal 174 100 vii-! ···. error signal 176 is generated by subtracting the modulation signal 174 error signal 174 in the adder 120 to a level corresponding to the attenuator 112 attenuated output signal 172.

Let us now take a closer look at the expected value generation of the modulation signal 174. Both modulation signal 174 and error signal 176 are supplied to 4 105366 quadrature demodulator 128 which generates phase control signal 180 and amplitude control signal 182 using known quadrature demodulator multipliers 160 in phase shift 162 and signal divider 164 in a known manner. effectively averaged in the integrator 122. The thus processed and effectively averaged phase control signal 186 distorts the amplifiable signal 100 in the phase distorting means 116. Similarly, an amplitude control signal 182 is generated which is also low pass filtered in the filter 134, and efficiently averaging the amplitude control signal 184 to distort signal to be amplified than the amplitude distorting instrument 100 114. Such averaging distortion of phase and amplitude modulation signal 174 makes a signal to be amplified the expected value of 15 to 100 by taking into account term integrators 122 and 130. That is, error signal 176 only indicates rapid changes in signal 100 to be amplified, since slow changes are summed up.

The solution of the invention rapidly changes phase and amplitude distortion by means 104 and 106 according to how much the error signal 176 20 differs from the modulation signal 174, which corresponds to the expected value, or average value, of the signal to be amplified 100. Thus, the inventive solution is adaptive to changes in the t: V: hip. The adaptivity is implemented by providing the distortion controller 110 with high-pass filtered steps 136 and 138; and amplitude control signals 184 and 186. With these signals and the amplifier

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·. 25 signals are used to select the appropriate predistortion information from the table.

Let us now examine the selection of the pre-distortion data in accordance with the invention. Fig. 2 illustrates a distortion controller 110 comprising a first ... low-pass filter 200, an A / D converter 202, a first memory · 204, a second memory 206, a D / A converter 208, a second low-pass filter 30. 210, a second D / A converter 212, and a third low pass filter: * · .. 214. Controller 110 operates as follows. First low-pass filter 200 removed · * ·. then, the signal * · · is converted to a digital converter 202. The digital signal is used to directly control the memories 204 and 206, of which the memory 204 controls the phase pre-distortion and the memory 206 controls the amplitude pre-distortion. The digital data of the phase pre-distortion is converted to analog in the first D / A converter 208 and filtered by the second low pass filter 210. Similarly, the amplitude pre-distortion digital data is converted to analog in the second D / A converter 212 and filtered by the third low-pass control. and usually 5 radio frequency pre-distortion means 104 and 106 in known manner to distort phase and amplitude.

Although the amplitude and phase of the polar variables are presented as separate variables, they can still be marked and treated as a single variable using a complex representation and treating the variables as if they were 10 vectors. Hereby a variable a, a = g + jp can be defined, where j is the imagine unit and g is the amplitude and p is the phase. The variable a can also be denoted by the unit vectors of amplitude G and phase P a = gG + pP. The signals 100, 184 and 186 entering the memory 204 and 206 of the distortion controller 110 may be represented in this form and thus, for example, the two control signals 184 and 15 186 may be replaced by a single complex signal which in turn may be represented in digital form. The memory 204, 206 is preferably a RAM memory having a plurality of input ports for signals 100, 184, and 186. The memory 204, 206 is preferably a dual-port RAM memory storing various amplitude and phase preset information.

20 Because memory 204, 206 is digital, memory only accepts sequentially.

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\ v amplitude and phase values generated at the time of sampling. Thus new: V: The distortion control parameter a „+ i, which corresponds, for example, to signals 184 and 186 or to signal 100, is generally obtained from the previous parameter Il Il * • j a α by the following formula:« «· · 25 an + l = a „- KVE [v *], III * * · · · · ... where E is the expected value operator, an is the current parameter used to modify the signal, · · dd ..., K is the gain factor, V = - G + - P denotes the nabla-::: dg öp '30 operator to form a vector-shaped part of the scalar function ···. a derivative of orthogonal unit vectors G and P. Usually, this partial derivative, also called a gradient, is replaced by multiplying the modulation signal 174 vm and the error signal 176 ve by αη + ι = a „- Kvmve. This multiplication corresponds to quadrature demodulation in the means 120 and the expectation value of the original expression is included in the average gain of the modulation signal 174.

Although the invention has been described above with reference to the example of the accompanying drawings, it is to be understood that the invention is not limited thereto but that it can be modified in many ways within the scope of the inventive idea set forth in the appended claims.

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Claims (10)

A linearization method, in which a signal (100) to be amplified is distorted by utilizing in a memory (202,204) stored digital pre-distortion information, characterized in that the signal (100) to be amplified is distorted in its analog form, the pre-distortion is adapted according to the signal (100) to be amplified, the pre-distortion information stored in the memory (202, 204) corresponds to the variables of a polar coordinate system, such as phase and amplitude, and at the pre-distortion the phase and amplitude of the signal (100) to be amplified according to the pre-distortion information are distorted. . 10 Method according to claim 1, characterized in that the pre-distortion is adapted according to the signal (100) which is to be amplified in such a way that the memory (202, 204) containing stored digital pre-distortion information is controlled by using the signal (100) which is to be amplified on the signal. means that the signal (100) to be amplified is converted to digital form prior to the control of memory (202,204). Method according to claim 1, characterized in that, as a waiting value for the signal (100) to be amplified, a modulation signal (174) and an error signal (176) is formed between the amplified signal (172) and the modulation signal (174), quadrature is modulated the modulation signal (174). ) and the error signal (176) to form a control signal (180,182) for the distortion, "" v: and the pre-distortion is adapted according to the signal (100) which should: V: be amplified in such a way that the memory (202, 204) is controlled by in addition to the signal (100) to be amplified, use the control signal (180, 182) for the distortion in such a way that the control signal (180,182) is also converted to digital form before the control of the memory (202, 204). ! ·. Method according to claim 2, characterized in that the pre-distortion information is stored in a look-up table memory with several input ports. • · · 5. A method according to claim 1, characterized in that the pre-distortion means (104, 106) are analogous to the pre-distortion information originating from the memory (202, 204) with which the pre-distortion means (104, * 106). is controlled, converted to analog form. 6. Amplifier arrangement, comprising pre-distortion means (104 and · 106) and a memory (202 and 204) in which digital pre-distortion information is stored, characterized by the pre-distortion means (104 and 106) has been arranged to distort the signal (100) to be amplified in its analog form, the receiver arrangement has been arranged to adapt the pre-distortion according to the signal to be amplified, the pre-distortion information stored in the memory (202, 204) corresponds to the phase and amplitude variables. a polar coordinate system, and the pre-distortion means have been arranged to distort the phase and amplitude of the signal according to the pre-distortion information. Amplifier arrangement according to patent claim 6, characterized in that the pre-distortion means (104 and 106) are arranged to adapt the pre-distortion according to the signal (100) to be amplified in such a way that an analog-digital converter (202) converts the signal (100) to be amplified into digital form and after conversion. For example, the digital signal (100) has been arranged to control the memory (202,204) which contains stored digital pre-distortion information. 8. Amplifier arrangement according to claim 6, characterized in that the amplifier arrangement is arranged to produce as a waiting value for the signal (100) to be amplified an error signal (176) between the modulation signal 15 (174) and the output signal (172) for the modulation signal (174). (120) has been arranged to demodulate the modulation signal (174) and the error signal (176) to form a control signal (180,182), and the pre-distortion means (104 and 106) have been arranged to adapt the pre-distortion except according to the signal (100) to be amplified also according to the .: the control signal (180, 182) in such a way that the analog-to-digital converter (203) has: Y: arranged to convert the control signal (180, 182) into digital form and after the conversion, the control signal has also been arranged to control the memory (202, 204) stored digital pre-distortion information. • · · ·: ·. 25 9. Amplifier arrangement according to claim 6, characterized in that the pre-distortion information is stored in a look-up table memory with several input ports. 10. Amplifier arrangement according to claim 6, characterized in that the pre-distortion means (104, 106) are analogous, and that digital analog transformers (208, 212) have been arranged to convert to analog form that of the memory (202,: ·). ... 204) the output pre-distortion information intended to control! ···. the pre-distortion means (104,106). IM 'a I I I a a a a a a a __ aa